Click here to open the tutorial patch and files: [[Media:05yFMSynth.zip]]

−

In this tutorial, we'll look at using frequency modulation to generate more musical tones by applying the principle of FM to a synthesis algorithm that can generate complex timbres that vary over time. ===Elements of FM synthesis===

+

In this tutorial, we'll look at using frequency modulation to generate more musical tones by applying the principle of FM to a synthesis algorithm that can generate complex timbres that vary over time.

+

+

===Elements of FM synthesis===

Frequency modulation (FM) has proven to be a very versatile and effective means of synthesizing a wide variety of musical tones. Because it allows for the generation of complex spectra that can vary over time, it is very good for emulating acoustic instruments. In addition, the fact that it uses very few oscillators to produce complex sounds makes it computationally efficient compared to producing the same effects with additive synthesis.

Frequency modulation (FM) has proven to be a very versatile and effective means of synthesizing a wide variety of musical tones. Because it allows for the generation of complex spectra that can vary over time, it is very good for emulating acoustic instruments. In addition, the fact that it uses very few oscillators to produce complex sounds makes it computationally efficient compared to producing the same effects with additive synthesis.

Line 9:

Line 11:

Because of these relationships, it's possible to boil the control of FM synthesis down to two crucial values, which are defined as ratios of the pertinent parameters. One important value is the ''harmonicity ratio'', defined as ''Fm/Fc''; this will determine what frequencies are present in the output tone, and whether the frequencies have an harmonic or inharmonic relationship. The second important value is the ''modulation index'', defined as ''Am/Fm;'' this value affects the ‘brightness’ of the timbre by affecting the relative strength of the partials.

Because of these relationships, it's possible to boil the control of FM synthesis down to two crucial values, which are defined as ratios of the pertinent parameters. One important value is the ''harmonicity ratio'', defined as ''Fm/Fc''; this will determine what frequencies are present in the output tone, and whether the frequencies have an harmonic or inharmonic relationship. The second important value is the ''modulation index'', defined as ''Am/Fm;'' this value affects the ‘brightness’ of the timbre by affecting the relative strength of the partials.

−

---- '''Technical detail:''' In John Chowning's article ‘Synthesis of Complex Audio Spectra by Means of Frequency Modulation’ and in Curtis Roads' Computer Music Tutorial, they write about the ratio ''Fc/Fm''. However, in F.R. Moore's Elements of Computer Music he defines the term harmonicity ratio as ''Fm/Fc''. The idea in all cases is the same, to express the relationship between the carrier and modulator frequencies as a ratio. In this tutorial we use Moore's definition because that way whenever the harmonicity ratio is an integer the result will be a harmonic tone with ''Fc'' as the fundamental. ----

+

----

+

+

'''Technical detail:''' In John Chowning's article ‘Synthesis of Complex Audio Spectra by Means of Frequency Modulation’ and in Curtis Roads' Computer Music Tutorial, they write about the ratio ''Fc/Fm''. However, in F.R. Moore's Elements of Computer Music he defines the term harmonicity ratio as ''Fm/Fc''. The idea in all cases is the same, to express the relationship between the carrier and modulator frequencies as a ratio. In this tutorial we use Moore's definition because that way whenever the harmonicity ratio is an integer the result will be a harmonic tone with ''Fc'' as the fundamental.

+

+

----

The frequencies of the sidebands are determined by the sum and difference of the carrier frequency plus and minus integer multiples of the modulator frequency. Thus, the frequencies present in an FM tone will be ''Fc'', ''Fc''+''Fm,'' ''Fc-Fm'', ''Fc+2Fm'', ''Fc-2Fm'', ''Fc+3Fm'', ''Fc-3Fm'', etc. This holds true even if the difference frequency turns out to be a negative number; the negative frequencies are heard as if they were positive. The number and strength of sidebands present is determined by the modulation index; the greater the index, the greater the number of sidebands of significant energy.

The frequencies of the sidebands are determined by the sum and difference of the carrier frequency plus and minus integer multiples of the modulator frequency. Thus, the frequencies present in an FM tone will be ''Fc'', ''Fc''+''Fm,'' ''Fc-Fm'', ''Fc+2Fm'', ''Fc-2Fm'', ''Fc+3Fm'', ''Fc-3Fm'', etc. This holds true even if the difference frequency turns out to be a negative number; the negative frequencies are heard as if they were positive. The number and strength of sidebands present is determined by the modulation index; the greater the index, the greater the number of sidebands of significant energy.

Line 19:

Line 25:

* Double-click on the <code>simpleFM~</code> abstraction object to see its contents.

* Double-click on the <code>simpleFM~</code> abstraction object to see its contents.

The main asset of this abstraction is that it enables one to specify the carrier frequency, harmonicity ratio, and modulation index, and it then calculates the necessary modulator frequency and modulator amplitude (in the {{maxword|name=*~}} objects) to generate the correct FM signal. The abstraction is flexible in that it accepts either signals or numbers in its inlets, and the harmonicity ratio and modulation index can be typed in as arguments in the main patch.

The main asset of this abstraction is that it enables one to specify the carrier frequency, harmonicity ratio, and modulation index, and it then calculates the necessary modulator frequency and modulator amplitude (in the {{maxword|name=*~}} objects) to generate the correct FM signal. The abstraction is flexible in that it accepts either signals or numbers in its inlets, and the harmonicity ratio and modulation index can be typed in as arguments in the main patch.

Latest revision as of 16:17, 6 July 2012

In this tutorial, we'll look at using frequency modulation to generate more musical tones by applying the principle of FM to a synthesis algorithm that can generate complex timbres that vary over time.

Contents

Frequency modulation (FM) has proven to be a very versatile and effective means of synthesizing a wide variety of musical tones. Because it allows for the generation of complex spectra that can vary over time, it is very good for emulating acoustic instruments. In addition, the fact that it uses very few oscillators to produce complex sounds makes it computationally efficient compared to producing the same effects with additive synthesis.

Modulating the frequency of one wave with another wave generates many sidebands, resulting in many more frequencies in the output sound than were present in the carrier and modulator waves themselves. As was mentioned briefly in the previous chapter, the frequencies of the sidebands are determined by the relationship between the carrier frequency (Fc) and the modulator frequency (Fm); the relative strength of the different sidebands (which affects the timbre) is determined by the relationship between the modulator amplitude (Am) and the modulator frequency (Fm).

Because of these relationships, it's possible to boil the control of FM synthesis down to two crucial values, which are defined as ratios of the pertinent parameters. One important value is the harmonicity ratio, defined as Fm/Fc; this will determine what frequencies are present in the output tone, and whether the frequencies have an harmonic or inharmonic relationship. The second important value is the modulation index, defined as Am/Fm; this value affects the ‘brightness’ of the timbre by affecting the relative strength of the partials.

Technical detail: In John Chowning's article ‘Synthesis of Complex Audio Spectra by Means of Frequency Modulation’ and in Curtis Roads' Computer Music Tutorial, they write about the ratio Fc/Fm. However, in F.R. Moore's Elements of Computer Music he defines the term harmonicity ratio as Fm/Fc. The idea in all cases is the same, to express the relationship between the carrier and modulator frequencies as a ratio. In this tutorial we use Moore's definition because that way whenever the harmonicity ratio is an integer the result will be a harmonic tone with Fc as the fundamental.

The frequencies of the sidebands are determined by the sum and difference of the carrier frequency plus and minus integer multiples of the modulator frequency. Thus, the frequencies present in an FM tone will be Fc, Fc+Fm,Fc-Fm, Fc+2Fm, Fc-2Fm, Fc+3Fm, Fc-3Fm, etc. This holds true even if the difference frequency turns out to be a negative number; the negative frequencies are heard as if they were positive. The number and strength of sidebands present is determined by the modulation index; the greater the index, the greater the number of sidebands of significant energy.

The simpleFM~ object in this tutorial patch is not an MSP object; it's an <link type="vignette" module="core" name="abstractions">abstraction</link> that implements the ideas of harmonicity ratio and modulation index.

Double-click on the simpleFM~ abstraction object to see its contents.

The simpleFM~ abstraction

The main asset of this abstraction is that it enables one to specify the carrier frequency, harmonicity ratio, and modulation index, and it then calculates the necessary modulator frequency and modulator amplitude (in the *~ objects) to generate the correct FM signal. The abstraction is flexible in that it accepts either signals or numbers in its inlets, and the harmonicity ratio and modulation index can be typed in as arguments in the main patch.

In the main patch, the carrier frequency and harmonicity ratio are provided to simpleFM~ as constant values, and the modulation index is provided as a time-varying signal generated by the envelope using the function object.

Because modulation index is the main determinant of timbre (brightness), and because the timbre of most real sounds varies over time, the modulation index is a prime candidate to be controlled by an envelope. This timbre envelope may or may not correspond exactly with the amplitude of the sound, so in the main patch one envelope is used to control amplitude, and another to control brightness.

Each of the presets contained in the preset object have settings to produce a different kind of FM tone, as described below.

Turn audio on and click on the first preset in the preset object to recall some settings for the instrument. Click on the button to play a note. Adjust the gain~ slider to a comfortable volume, as some presets are louder than others. To hear each of the different preset tones, click on a different preset in the preset object to recall the settings for the instrument, then click on the button to play a note.

Preset 1. The carrier frequency is for the pitch C an octave below middle C. The non-integer value for the harmonicity ratio will cause an inharmonic set of partials. This inharmonic spectrum, the steady drop in modulation index from bright to pure, and the long exponential amplitude decay all combine to make a metallic bell-like tone.

Preset 2. This tone is similar to the first one, but with a (slightly mistuned) harmonic value for the harmonicity ratio, so the tone is more like an electric piano.

Preset 3. An ‘irrational’ (1 over the square root of 2) value for the harmonicity ratio, a low modulation index, a short duration, and a characteristic envelope combine to give this tone a quasi- pitched drum-like quality.

Preset 4. In brass instruments the brightness is closely correlated with the loudness. So, to achieve a trumpet-like sound in this example the modulation index envelope essentially tracks the amplitude envelope. The amplitude envelope is also characteristic of brass instruments, with a slow attack and little decay. The pitch is G above middle C, and the harmonicity ratio is 1 for a fully harmonic spectrum.

Preset 5. On the trumpet, a higher note generally requires a more forceful attack; so the same envelope applied to a shorter duration, and a carrier frequency for the pitch high C, emulate a staccato high trumpet note.

Preset 6. The same pitch and harmonicity, but with a percussive attack and a low modulation index, give a xylophone sound.

Preset 7. A harmonicity ratio of 4 gives a spectrum that emphasizes odd harmonics. This, combined with a low modulation index and a slow attack, produces a clarinet-like tone.

Preset 8. Of course, the real fun of FM synthesis is the surreal timbres you can make by choosing unorthodox values for the different parameters. Here, an extreme and wildly fluctuating modulation index produces a sound unlike that produced by any acoustic object.

You can experiment with your own envelopes and settings to discover new FM sounds. When you have finished, click on the ezdac~ to turn audio off.

As with amplitude modulation, frequency modulation can also be performed using complex tones. Sinusoids have traditionally been used most because they give the most predictable results, but many other interesting sounds can be obtained by using complex tones for the carrier and modulator signals.

FM synthesis is an effective technique for emulating acoustic instrumental sounds as well as for generating unusual new sounds.

The frequencies present in an FM tone are equal to the carrier frequency plus and minus integer multiples of the modulator frequency. Therefore, the harmonicity of the tone can be described by a single number - the ratio of the modulator and carrier frequencies - sometimes called the harmonicity ratio. The relative amplitude of the partials is dependent on the ratio of the modulator's amplitude to its frequency, known as the modulation index.

In most acoustic instruments, the timbre changes over the course of a note, so envelope control of the modulation index is appropriate for producing interesting sounds. A non-integer harmonicity ratio yields an inharmonic spectrum, and when combined with a percussive amplitude envelope can produce drum-like and bell-like sounds. An integer harmonicity ratio combined with the proper modulation index envelope and amplitude envelope can produce a variety of pitched instrument sounds.